Reference generator and current source transistor based on complementary current field-effect transistor devices

ABSTRACT

Existing proportional to absolute temperature (PTAT)/complementary-to-absolute-temperature (CTAT) reference voltage circuit requires a large components count and foot print, precise device matching for accuracy and unsatisfactory sensitivity error or variation to temperature and humidity. The present invention relates to a novel approach for such reference voltage circuit based on a self-biased complementary pair of n-type and p-type current field-effect transistors, which provides rail PTAT, rail CTAT and analog reference voltages.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application claims priority to U.S. Provisional Application No. 62/198,960, filed on Jul. 30, 2015; and U.S. Provisional Application No. 62/268,983, filed on Dec. 17, 2015, the contents of which is incorporated herein by reference in their entirety.

BACKGROUND OF THE INVENTION Field of the Invention

The present invention relates to a reference generator and current source transistor based on a novel and inventive compound device structure, enabling a charge-based approach that takes advantage of sub-threshold operation, for designing analog CMOS circuits.

Description of Related Art

The new millennium brings with it a demand for connectivity that is expanding at an extremely rapid pace. By the end of year 2015, the number of global network connections will exceed two times the world population and it is estimated that in 2020 more than 30 billion devices will be wirelessly connected to the cloud forming the Internet of Things (or “IoT”). Enabling this new era are the revolutionary developments in mobile computing and wireless communication that have arisen over the last two decades. Following Moore's Law, development of highly-integrated and cost-effective silicon complementary metal oxide semiconductor (CMOS) devices allowed incorporation of digital and analog system elements, such as bulky Analog-to-Digital converters or transceivers, into a more cost effective single chip solution.

In the last few years, however, while digital circuits have largely followed the predicted path and benefited from the scaling of CMOS technology into ultra-deep submicron (sub-μm), analog circuits have not been enabled to follow the same trend, and may never be enabled without a paradigm shift in analog design. Analog and radio frequency (or “RF”) designers still struggle to discover how to make high-performance integrated circuits (or “ICs”) for ultra-deep sub-μm feature sizes without losing the benefits of shrinking size; including reduced power, compact footprint, and higher operational frequencies. Truly a paradigm shift is needed to break through the established science of analog design to meet the system on chip (SoC) demands of the new millennium.

PRIOR ART

The core building block of analog circuits is the amplifier. Discrete component amplifiers are free to use resistors, capacitors, inductors, transformers, and non-linear elements as well as various types of transistors. Unwanted parasitics between various components are normally negligible. However, in order to build amplifiers within an integrated circuit, the normal analog circuit components are not readily available, and often take special IC process extensions to obtain these circuit elements if at all. The parasitics on integrated circuit amplifiers are severe due to their close proximity and being coupled together through the silicon wafer they are integrated into. Moore's law IC process advancements are focused on digital, microprocessor, and memory process development. It takes a generation (˜18 months) or two to extend the IC process to incorporate analog components, thus analog functionality is generally not included on the latest process single chip systems. These “mixed-mode” IC processes are less available, vender dependent, and more expensive as well as being highly subject to parametric variation. It takes substantial engineering to include sparse analog functionality on any IC which becomes specific to its IC vender and process node. Because analog circuitry is carefully and specifically designed or arranged for each process node, such analog circuitry is highly non-portable. Reprobating this limitation, analog circuit design engineers are becoming scarce and are slowly retiring without adequate replacements.

Operational Amplifiers (or OpAmps) are the fundamental IC analog gain block necessary to process analog information. OpAmps make use of a very highly matched pair of transistors to form a differential pair of transistors at the voltage inputs. Matching is a parameter that is readily available on an integrated circuit, but to approach the required level of matching, many considerations are used: like centroid layout, multiple large devices, well isolation, and physical layout techniques among many other considerations. Large area matched sets of transistors are also used for current mirrors and load devices. OpAmps require current sources for biasing. OpAmps further require resistor and capacitor (or RC) compensation poles to prevent oscillation. Resistors are essential for the “R” and the value of the RC time constant is relatively precise. Too big value for a resistor would make the amplifier too slow and too small results in oscillation. Constant “bias” currents add to the power consumed. In general, these bias currents want to be larger than the peak currents required during full signal operation.

As IC processes are shrunk, the threshold voltages remain somewhat constant. This is because the metal-oxide-semiconductor (or MOS) threshold cutoff curve does not substantially change with shrinking of the IC processes and the total chip OFF leakage current must be kept small enough to not impact the full-chip power supply leakage. The threshold and saturation voltage tends to take up the entire power supply voltage, not leaving sufficient room for analog voltage swings. To accommodate this lack of signal swing voltage, OpAmps were given multiple sets of current mirrors, further complicating their design, while consuming more power and using additional physical layout area. This patent introduces amplifier designs that operate even better as power supply voltages are shrunk far below 1 volt.

The conventional MOS amplifier gain formation is an input voltage driving a trans-conductance (g_(m)) which converts the input voltage into an output current. This output current then drives an output load which is normally the output of a current source for the purpose of establishing a high load resistance. This high resistance load converts the output current back into an output voltage. The equivalent output load resistance is actually the parallel combination of the load current source transistor and the amplifier output transistors. In order to keep this equivalent load resistance high to provide the required voltage gain, these load transistors must be very long, but to drive enough current these transistors must be very wide also, thus very large transistors are necessary. It also might be noted that the load resistance the amplifier output drives is additional parallel resistance that reduces the voltage gain. It should also be noted that a load capacitance interacts with the amplifiers output resistance, modifying the AC performance. What is actually needed is exactly the inverse operating principle, which the present invention is about. FIG. 1a is a transistor level schematic diagram of a high-quality MOS IC OpAmp as a baseline reference (from the Wiley textbook: Analysis and Design of Analog Integrated Circuits by Gray and others, 4^(th) edition pg. 482) which is used for comparison in the description of the amplifiers illustrated herein.

The baseline comparisons are (all made in an 180 nm IC process) in the form of performance plots as in: a Bode Gain-Phase plot over frequency FIG. 1b , when V_(dd)=1.8 Volts and R_(cmp)=700 ohms. Wherever possible all the axis scales for each of these three comparison plots are kept the same. A readily available 180 nm process was selected for comparison of all the comparative examples in this document because the conventional prior art amplifiers work best and have had the most usage and have mature mixed-mode IC process extensions offered which are required for conventional analog. Also as the IC process is shrunk and the power supply voltage is decreased, this is where the implementations of the present invention become highly beneficial.

Normally MOS amplifiers operate within a square-law relationship due to the strong inversion MOS transistor square-law characteristics; these are not very well defined or predictably stable to the degree that analog circuits need. Exponential-law operation, like bipolar transistors operation is higher gain, stable, and well defined. At very weak operating conditions, MOS transistors convert to exponential operation, but they are too slow to be of very much use. Furthermore, the “moderate-inversion” transition between these two operating mode provide non-linearities that lower the quality of analog MOS circuits. At the threshold voltage, where MOS transistors operate around, is where 50% of the current is square-law and the other 50% is exponential. This is the definition of threshold voltage in the latest MOS simulation equations. Full exponential MOS operation at high speed would provide higher gain that is predictable, stable, and well defined. This patent is about amplifiers that operate in the exponential mode.

To understand the prior art, let's begin with a discussion of Weak vs. Strong inversion. Referring to FIGS. 1e and 1f , weak inversion is the range where most designers would consider the transistor to be OFF:

-   -   Drain to Source voltage is small (on the order of 100 mV);     -   The gate G (or 17 s) is at a similar small potential (typically         less than 300 mV);     -   This creates a surface conduction layer, of uniform depth from         source S to drain D;     -   The conductivity of this surface layer is exponential with         respect to the Gate G voltage;     -   This allows operation over many decades (about 6) of dynamic         range;     -   The channel appears as a moderate value resistor (100⁺s of         K-Ohms); and     -   The uniform depth conduction channel promotes an exponentially         higher gain but with a speed penalty (due to low charge density         in the conduction channel).

Strong inversion (referring to FIGS. 1g & 1 h) is characterized by a graduated conduction channel, deeper near the Source and shallow near at the Drain:

-   -   Drain to Source voltage is larger than the Gate to Source         voltage Vg of FIG. 1g and threshold V_(threshold) in FIG. 1h         (typically in excess of 400 mV);     -   The Gate 17 u is operated above its threshold voltage         V_(threshold);     -   This creates a conduction channel that is deeper at the Source         and tapers to near pinch-off at the Drain 12 u;     -   The resulting conduction layer behaves with a Square-law         response to the gate voltage at the Gate 17 u;     -   Dynamic range is limited to about 3 decades as compared to weak         inversion;     -   The channel 12 g appears as an adjustable current source (high         value resistor);

and

-   -   The wedge shape of the conduction channel 12 g provides higher         speed than weak inversion because of higher charge density in         the conduction channel.

Now, referring back to FIG. 1e , which shows the channel 12 e development under weak inversion conditions. The conduction channel 12 e has a relatively even distribution of carriers over its entire length and width. Note that the conduction depth 10 s of the entire channel is the same as the pinch-off area 12 u on the right side of FIG. 1g . This thin conduction layer contributes a significant amount of noise because the channel current travels along the surface where charge carrier defect traps are concentrated. The Gate 17 s to channel voltage V_(g) in FIG. 1e has a strong (exponential) effect on the density of carriers in this conduction layer.

FIG. 1g shows the channel 12 u development under Strong inversion conditions. The higher potential difference between Source and Drain over the gate 17 u causes “channel length modulation” (the flat part of the channel 12 u), resulting in pinch-off near the drain diffusion where the channel reaches a thin layer near 12 u. The pinch-off region 12 u (where the carriers are forced to the top of the channel) imparts significant noise by means of surface defect carrier traps. The higher the drain voltage V_(d), the longer the pinch-off region and thus the higher the contributed noise, thus it is desired to keep this voltage low for low noise contribution to the channel current. Other effects such as velocity saturation and hot electron jumping over into the gate oxide are noted around this thin saturated pinch-off region, thus it would be highly desirable to minimize this region by lower voltage and semiconductor doping profiles.

FIG. 1h shows a characteristic plot which approaches a “constant current” relationship between drain current I_(d) and drain voltage V_(ds) with a fixed Gate voltage V_(g) on the gate G. It is to be noted that the drain voltage V_(ds) spans a large range of nearly the power supply voltage V_(dd), while maintaining the same current as opposed to the limited drain voltage range of FIG. 1 f.

FIG. 1i to 1k illustrate a prior art MOS structure, commonly known as a CMOS inverter, that turns out to actually combine both modes of operation. A pair of MOSFETs with opposite conductivities, PFET and NFET, are complementary connected with each other. For example, the input 10 i, 10 j, 10 k is connected to both the gate control terminal of PFET and the gate control terminal of NFET, the source of PFET is connected to power supply (+), while the source terminal of NFET is connected to power supply (−); and the drain of PFET and the drain of NFET connected together for V_(out) 19 i.

FIG. 1j shows the structure related to a physical layout abstraction shown in FIG. 1k , which is 2× strength CMOS or two-finger inverter of prior art. As stated above, gate terminals of PFET and NFET are connected together to receive V_(input) 10 j and 10 k and the drain terminals of PFET and NFET are connected together for producing V_(output) 19 j and 19 k. The layout shown in FIG. 1k structurally corresponds to that of FIG. 1i . As it can be seen, to minimize various shortcoming from the conventional FET layouts, such as minimizing parasitic output capacitance, the source terminal of PFET, for example, is split into two source terminals S+ and S+, and the drain terminal D+ 12 k is displaced therebetween for forming a pair of parallel channels 14 k and 16 k between S+ and D+ 12 k; p-channel region of the gate G covers the parallel channels 14 k and 16 k. Divided by the well border WB, NFET is also provided with a pair of source terminals, S− and S−, and the drain terminal thereof, D− 11 k is displaced therebetween for forming a pair of parallel channels 13 k and 15 k between S− and D−; n-channel region of the gate G further covers the parallel channels 13 k and 15 k. Drains 12 k and 11 k are connected therebetween through metal work 18 k and forms V_(output) 19 k.

A 3-dimensional prospective view of this MOS transistor structure is shown in FIG. 1m , while cross sectional view at section AA in FIG. 1m is shown in FIG. 1n . This structure is inherent in a 2× or two-finger inverter as shown in FIGS. 1j and 1k . As it can be seen therein at the parallel channels 14 k and 16 k in PFET and the parallel channels 13 k and 15 k, all of these channels taper from the drains D+, D− to the sources S+, S−.

Although similar MOS structures appear in prior art, no significant exploitation of many of its unique properties are known or published. In addition, proper biasing remains as a problem(s) for its operation(s). A deeper understanding of the internal mechanisms resulted in discovery of many desirable applications (enabling superior operation at deep-sub-micron scale), including an approach to proper biasing that takes advantage of natural equilibrium. This natural equilibrium is the result of a “Band-Gap” voltage reference mechanism, again functional at deep-sub-micron scale.

Referring to FIGS. 1p and 1q , some references show a MOS field effect transistor device with two identical regions 13 p/13 q and 15 p/15 q of like “conductivity type” separated by a diffusion region 11 p (designated as Z for Low Impedance in the prior art). Multiple papers by Bedabrata Pain/R Schober, Jet Propulsion Lab and Jacob Baker/Vishal Saxena, Boise State University, including Pain, Bedabrata et al., “A Self-Cascoding CMOS Circuit for Low-Power Applications”, Center for Space Microelectronics Technology Jet Propulsion Laboratory, California Institute of Technology, contain such references, but these references do not exploit any opportunities as shown in this document, especially when complementary devices like this are combined into a single composite device as will be explained in this invention. Such configurations have been called self-cascading or split-length devices. The two regions of such a configuration are arranged between source and a drain diffusions and have both a high impedance common gate connection and a low impedance connection to the mid channel regions. This low impedance mid channel control input, when exploited as outlined in this document, enables an entirely new set of analog design methods.

Although a cascade amplifier can be found in prior art, the prior art does not contain a complementary pair of cascade transistors connected as a totem-pole. With this simple compound structure, feedback from the output to the input can be used to self-bias the resulting inverter into its linear mode. As mentioned above, biasing of an amplifier has always been problematic; however, the novel and inventive self-biasing structure of the present invention addresses such an issue. Advantages of the configuration of the present invention (referred to as a complementary iFET or CiFET) are many, including, but not limited to:

-   -   Gain of the single stage is maximum when the output is at the         midpoint (self-bias point);     -   The gain of a single CiFET stage is high (approaching 100),         therefore, while the final output may swing close to the rails,         its input remains near the midpoint. The stage before that,         because of the high gain, operates its input and output near the         mid-point (“sweet-spot”) where the gain is maximized. So too for         each of the preceding stages;     -   Slew rate and symmetry are maximized where the channel current         is highest (near the mid-point);     -   Noise is minimized where the channel current is highest (near         the mid-point); and     -   Parasitic effects are negligible where the voltage swing is         small.

When the gate input signal moves in one direction, the output moves in the inverse direction. For example; a positive input yields a negative output, not so much because the N-channel device is turned on harder, but rather because the P-channel device is being turned off. Thevenin/Norton analysis shows that the current through the P and N devices must be exactly the same, because there is nowhere else for drain current in one transistor to go except through the drain of the complementary transistor; however, the voltage drop across those devices does not have to be equal, but must sum to the power supply voltage. Due to the super-saturated source channel, these voltages are tied together exponentially. This is even more evident at low power supply voltages where the voltage gain peaks. This means that the gate-to-source voltage is precisely defined by the same and only drain current going through both transistors. Exponentials have the unique physical property like a time constant, or “half-life;” It does not matter where we are at a given point of time, a time constant later we will be a fixed percentage closer to the final value. This is a “minds-eye” illustration of the primary contributor to output movement in response to input change. This same current balance of gate-to-source operating voltages also indicates why the “sweet-spot” in the self-biased amplifier is so repeatable. In effect it is used as a differential pair-like reference point to the amplifier input signal.

It is to be noted that during the transition from vacuum tubes to bipolar transistors the industry underwent a major paradigm shift, learning to think in terms of current rather than voltage. With the advent of FETs & MOSFETs the pendulum swing is back toward thinking in terms of voltage, but much knowledge has been lost or forgotten. Herein is contained the rediscovery of some old ideas as well as some new ones, all applied to the up-coming “current” state of the art. It is believed that the inherent simplicity of the present invention speaks to their applicability and completeness.

A first issue may be that there is always a need for a little analog functionality, yet nearly all analog performance metrics of a MOS transistor are remarkably poor as compared to that of a Bipolar transistor. The industry has made MOS devices serve by employing extensive “work-arounds.” Conventional analog design is constrained by one or more of the followings:

-   -   Power supply voltages sufficient to bias the stacked thresholds,         and transistors large enough to supply the necessary output         drive current while still providing the high output impedance         required for linearity and gain (g_(m)*R_(L)).     -   Lack of analog IC process extensions (unavailable at nanometer         scale) are required for linear signals, let alone with the         enhanced performance demonstrated herein.     -   Resistors, inductors, and large capacitors are mostly         non-existent for analog designs in newer IC processes.

In contrast, bipolar transistors can be made to have high gain (β), wider bandwidth, wider dynamic range (many decades, from near the rails down to the noise floor), better matching (found in differential pairs), and band-gap references. Junction FETs, which operate with sub-surface channel conduction below the surface defects, have lower noise than bipolar transistors. Likewise the CiFET super-saturated source channel operates primarily below the defects at the channel surface underneath the gate oxide.

MOS designs are poorer in the above areas but have their own extreme advantages, including, but not limited to:

-   -   MOS devices are small and relatively simple     -   highly scalable     -   high speed     -   low power     -   ultra-dense/high functionality systems on a chip, where Bipolar         designs cannot go (deep sub-μm scale).

Accordingly, building analog circuits on an IC has always been problematic. Engineering around poorly performing analog components has been the overriding objective for analog IC designers since analog circuits have been integrated. This drove the need for digital signal processing with algorithm development yielding digital magic.

Today the real-world of analog circuit design, signals still need to be converted on both the front and back end of signal processing systems. This need has become a road-block at deep sub-μm scale.

Another problem may be that solid-state amplifiers have been notoriously non-linear since their inception. To make them linear, increased open loop gain (with levels significantly higher than is ultimately needed) is traded for control over actual circuit gain and linearity through the use of a closed loop (feedback). A closed loop amplifier requires negative feedback. Most amplifier stages are inverting, providing the necessary negative feedback. A single stage inverter, with a closed loop, is stable (does not oscillate). Increased loop gain requires stages be added such that there are always an odd number of stages (sign is negative), to provide the necessary negative feedback. While a single stage amplifier is inherently stable, three stages and most definitely five stages are unstable (they always oscillate—because they are ring oscillators).

The problem then is how to properly compensate a multi-stage closed loop amplifier while maintaining a reasonable gain-bandwidth product. This is particularly difficult at deep-sub-micron scale where circuit stages must be simple in their design. The severely limited power supply voltages preclude the use of conventional analog design approaches. Additionally, it is desirable to avoid reliance upon analog extensions but rather to accomplish the necessary analog functions using all digital parts, to improve yields and decrease costs. Using all digital parts allows analog functions at process nodes that do not yet have analog extensions, and may never have them.

There is a long felt need for low-cost/high-performance systems integrated on a single chip for affordable high-volume devices such as the Internet of things, smart-sensors, and other ubiquitous devices.

SUMMARY OF THE INVENTION

The present invention relates to circuits built out of a novel and inventive compound device structure, which enables a charge-based approach that takes advantage of exponential relationships of a super-saturated source channel described in relation to FIGS. 2a, 2b, 2c and 2d below which possesses sub-threshold-like operation when used for analog CMOS circuit designs. The present invention is an evolution of an ordinary CMOS inverter. It provides extremely high precision, speed, linearity, low noise, and a compact physical layout, using an all-digital nanoscale or deep sub-μm IC process. In addition to the expected digital inverter function, five classes of analog circuits are exemplified: a voltage input amplifier, a current input amplifier, a current inverter as opposed to a current mirror, an adjustable delay circuit, and a voltage or current reference source. Take special note that analog functionality is realized, in a digital IC process, using a single optimized digital logic circuit cell.

According to another aspect of the present invention, it takes advantage of the Doping Profile and Ratioing. Not everything in optimizing a circuit has to do with the circuits' electrical configuration. Proper device sizing and especially adjusting the size relationship between complementary transistors provides considerable performance benefits. The iFET, being a compound structure, offers extensive opportunity to establish impedance matching and gain control through proper ratio of the physical device parameters. Other important characteristics, like noise, speed, and power, can be tailored through careful specification of the physical construction and doping of the transistors, rather than relying solely on circuit configuration.

According to yet another aspect of the present invention, it provides certain noise advantages. In the end, it comes down to signal-to-noise ratio. Low power supply voltage requirements in ultra-deep-sub-micron IC processes limit the maximum signal swing to a much smaller number than most analog designers are used to. So with a smaller signal, the low-noise techniques embodied herein must be employed in order to maintain the desired signal to noise ratio.

Additional Advantages may be provided by the present invention. The primary advantage delivered by this technology is the ability to produce analog building blocks constructed entirely from digital parts, without analog extensions. Equally important is the fact that it actually operates at ultra-deep-sub-micron scale, and operates best at reduced power supply voltages below one volt as required for ultra-deep sub-μm IC processes. These three factors contribute to an unprecedented portability of designs across process nodes. Entirely new circuit designs will be realized because of a FET that has more than one control input. The CiFET offers a high-impedance voltage control on the gate while simultaneously offering a low-impedance current control at the iPorts. These two inputs operate independently of each other and their independent response is summed at the output.

According to yet another aspect of the present invention, it provides a complementary iFET compound device, which can be configured as a reference generator and current source transistor or proportional-to-absolute-temperature (PTAT) reference voltage circuit and/or complementary-to-absolute-temperature (or CTAT) voltage reference voltage circuit.

BRIEF DESCRIPTION OF FIGURES

FIG. 1a illustrates a high quality CMOS OpAmp prior art transistor schematic from a prominent textbook “Analysis and Design of Analog Integrated Circuits,” 4^(th) Ed, by Gray, Hurst Lewis and Meyer, p 482 as a prior art amplifier for comparison;

FIGS. 1b to 1d are a baseline set of representative performance plots illustrating frequency domain performance and power supply dependency of the prior art OpAmp of FIG. 1 a;

FIGS. 1e and 1g show cross-sectional views of prior art MOSFET channel conduction in weak inversion and in strong inversion, respectively, and FIGS. 1f and 1h show plots bearing exponential relationship between drain current and gate voltage when in weak inversion and quadratic relationship when in strong inversion, respectively;

FIG. 1i shows a transistor schematic of two (2) finger inverters of prior art;

FIGS. 1j and 1k show physical layout abstractions of the two (2) finger inverters of prior art;

FIG. 1m shows a three (3) dimensional perspective view of the two (2) finger inverters of prior art;

FIG. 1n shows cross-sectional view at Section AA shown in FIG. 1 m;

FIG. 1p shows a physical layout of a split channel CMOS transistor of prior art;

FIG. 1q shows a 3D perspective view of an analog-sized MOSFET of prior art;

FIG. 1r shows a physical layout plan of an analog-sized array of Fin field effect transistors (FinFET) of prior art;

FIG. 1s shows a zoomed perspective view of inside the circle Z shown in FIG. 1r , showing a perspective view of a FinFET of prior art;

FIG. 1t shows a plot representing intrinsic gain scaling of nMOS transistor of prior art;

FIG. 2a illustrates a three (3) dimensional prospective view of a MOS field-effect transistor (or iFET) with a new mid-channel bi-directional current port (iPort) of the present invention;

FIG. 2b illustrates a cross-sectional view of iFET of the present invention with visualized channel charge distributions;

FIG. 2c shows a graph of drain voltage V_(ds) and drain current I_(s) when there is no iPort injection current, while FIG. 2d shows another graph when max iPort injection current is provided;

FIG. 2e shows various iFET symbols of the present invention;

FIG. 3a illustrates a schematic diagram of complimentary pair of iFETs of the present invention;

FIGS. 3b and 3c illustrate a physical layout abstraction of a complementary iFET (or CiFET) compound device of the present invention;

FIG. 3d shows a three (3) dimensional perspective view of the CiFET compound device;

FIG. 3e illustrates cross-sectional view at Section AA of FIG. 3 d;

FIGS. 3f, 3g and 3h illustrate a CiFET operational modeling, self-bias schematic and symbol therefor;

FIG. 3i illustrates a physical layout of NOR gate of a prior art;

FIG. 3j (1) illustrates a physical layout of seminal CiFET, FIG. 3j (2) illustrates its corresponding schematic diagram, and FIG. 3j (3) illustrates its corresponding symbol;

FIG. 3k illustrates a physical layout of FinFET of complimentary pair of iFET (equivalent to the CiFET symbol shown in FIG. 3j ) of the present invention;

FIG. 3m illustrates a schematic diagram of a proportional to absolute temperature (PTAT) circuit of prior art;

FIG. 4a shows a schematic diagram of a self-biased CiFET reference voltage outputs generating circuit, including ˜V_(dd)/2 analog virtual ground that analog voltages swing about, and proportional-to-absolute-temperature (or PTAT) and complementary-to-absolute-temperature (or CTAT) voltage reference outputs;

FIG. 4b shows a schematic diagram of a self-biased CiFET based positive and negative current references generator in accordance with the present invention;

FIG. 4c is a graph of CiFET PTAT and CTAT reference voltage linearity and tracking over extreme temperature;

FIG. 4d shows a self-biased CiFET based PTAT and CTAT stacked reference voltages generating circuit in accordance with the present invention; and

FIG. 4e shows a schematic diagram of reference voltages generator related to analog virtual ground (CiFET self-bias) voltage in accordance with the present invention.

DETAILED DESCRIPTION OF THE INVENTION

A MOS structure referred to herein as an iFET, where the letter “i” refers to a current and “FET” refers to a Field Effect Transistor, is the enabling element of several high performance and novel designs of the present invention. The present invention is based on the addition of a direct connection to a mid-point in a Field Effect Transistor (or FET) channel and the realization that this is a low impedance port (current port, or herein referred to as “iPort”) providing a bidirectional current sink/source mid-channel with a very low input impedance at a low saturation voltage, and additionally connecting reciprocal iFETs pairs of opposite “conductivity type” (P-type & N-type) interconnected to take advantage of their complementary nature to operate as a team and symmetry to self-bias near the midpoint between power supplies. In addition, the relative strength of the first and second channels of the iFETs can be adjusted (threshold choice, relative sizing, and doping profiles) to tailor the gain, speed, quiescent current and input impedance of such a complementary iFET (or CiFET) compound device of the present invention.

The iFET, with its iPort provides an uncommon and unexpected solution to the compensation problem, and then continues to provide new or alternative solutions to other old problems, exceeding industry expectations. The advantages of operating circuits in “weak inversion” have long been known but, so also have the problems. The CiFET enables circuits to exploit the high gain and wider dynamic range available in “weak inversion,” without sacrificing superior speed performance. The CiFET compound device provides a standard active IC gain device that is superior to ordinary analog MOSETs making digital ICs host analog functionality. It is not a tradeoff.

The following is a list of some of the unusual aspects of a CiFET based circuit, including, but not limited to:

-   -   Operates at low power supply voltage;     -   High gain;     -   Extremely linear;     -   Very high speed (wide band);     -   Self-Biasing;     -   Low noise;     -   Quick recovery (DC);     -   Uses all digital parts and processes;     -   iPorts respond to charge (things in nature are charge based)         rather than Volts across a Resistance; and     -   iPort has wide dynamic range with constant gain in an open loop.

Referring to FIGS. 2a and 2b , according to a preferred embodiment of the present invention, it provides a current FET (or iFET) 200, which is comprised of substrate 26 a or 26 b, source terminal 24 a or 24 b and drain terminal 29 a or 29 b, defining therebetween two channels 23 a and 25 a, or 23 b and 25 b on the substrate 26 a or 26 b, respectively, typically the first (source channel 23 a, or 23 b) is connected to the power supply (not shown) while the second (drain channel 25 a, or 25 b) connects to the load (not shown). The substrate 26 a or 26 b is N- or P-type. The two channels, source and drain channels 23 a and 25 a, or 23 b and 25 b, respectively, are connected to each other as shown in FIGS. 2a, and 2b , at the iPort control terminal 21 a or 21 b, and the channels 23 a and 25 a, or 23 b and 25 b, share a common gate control terminal 27 a or 27 b, respectively. This configuration means that the iFET 200 has more than one control input terminal.

The gate control terminal 27 a or 27 b operates like a conventional MOSFET insulated gate, with its high input impedance and a characteristic Trans-conductance (g_(m)) transfer function. Typical values of (g_(m)) for a small-signal MOSFET transistor are 1 to 30 millisiemens (1 millisiemen=1/1K-ohm) each, a measure of Trans-conductance.

The iPort control terminal 21 a or 21 b is low impedance with respect to the source terminal 24 a or 24 b, and has a transfer function that looks more like beta (β) of a bipolar transistor, but is actually Trans-resistance (or r_(m)), or more generally, especially at high frequencies, Trans-impedance, measured in K-ohms, where the output voltage is a consequence of an input current. Depending on the channel sizing ratio of the CiFET the typical resistance values (or values of r_(m)) for a small-signal iFET transistor 200 are from 1KΩ to 4MΩ, a measure of Trans-resistance. Current input to voltage output (Trans-impedance) is the basis for the assertion that 1 μA in will yield an output of 100 mV (or a gain of 100,000:1) at a large signal level, or 1 pA in will yield an output of 100 nanoV (or a gain of 100,000:1) in a low noise amplifier (or LNA) (both results from the same circuit and linear over this dynamic range).

These values have been shown to remain true for a single minimum sized iFET, with inputs from 1 pico-ampere to 10 micro-amperes, using the same circuit in simulation. In 180 nm CMOS construction the noise floor limits measurements below about 10 pico-amps. iFET's can be constructed with different length to width proportions with very predictably differing results.

High gain, uncharacteristic or surprising results differing from the state of the art designs, is the result of the “Weak inversion” characteristics of the source channel 23 b of the iFET 200 operating in a highly ionized super-saturation mode of FIG. 2 b.

Speed in this super-saturated source channel 23 b is not limited by the transit time of carriers along the channel 23 b, but the high concentration of ionized charge carriers in the active channel only have to push the surrounding charge a little as charge is either added or removed from the channel 23 b by means of the iPort control terminal 21 b, resulting in a diffusion current which is defined by exponential relationship as has been realized when a MOSFET is operated in weak-inversion. This is in contrast to an electric field causing the charge to transit the channel, which is a square-law function of the gate control voltage. In this configuration, speed is faster than logic built from the same fundamental transistors and unhampered by the “Weak inversion” stage that has higher gains like bipolar transistors. As opposed to bipolar transistors, control current can go either in or out of the iPort control terminal 21 b as well as operate with no iPort current, which is useful for creating a self-bias operating point.

Lower noise is facilitated by the self-biased operating point. Here the potential at drain terminal 29 a or 29 b is the same as potential at the gate control terminal 27 a or 27 b, greatly reducing the pinch-off effect found in conventional analog circuit designs.

The iFET 200, because of the common gate connection over the source channel 23 a/23 b and the drain channel 25 a/25 b, places a higher than expected voltage on the gate control terminal 27 a/27 b (or GS) of the source terminal 24 a/24 b or source channel 23 a/23 b. This higher than expected voltage is responsible for a much thicker and deeper (lower resistance highly ionized) conduction layer, allowing the majority of carriers to avoid the traps in the surface of the crystal lattice, hence—much lower noise similar to the manner in which a junction field effect transistor (or j-FET) conduction channel is located below the surface.

Trans-resistance (r_(m)) is the “dual” of Trans-conductance (g_(m)). When you look up Trans-resistance, most of the references are to inductors and capacitors, suggesting that the iFET may be useful in synthesizing inductors.

The iFET works in the following ways: A low noise amplifier requires a low impedance channel. A low impedance channel is low in voltage gain while high in current gain. To establish voltage gain, a second stage, operating as a current to voltage converter, is required. A cascaded pair provides such a configuration. Biasing requirements for a cascaded pair preclude its use at low voltage unless a solution for the biasing problem is found. The iFET provides the solution to this problem through self-biasing of a complementary pair. The impedance of the channel can be designed to accommodate the impedance of the particular signal source driving it (see later section on ratio).

Regarding FETs in general, carriers are attracted to the surface by the gate field, a low gate voltage creates a thin surface-layer on the channel (where the conductivity takes place) while a higher gate voltage creates a thicker under-layer. The thin layer of carriers is impeded by the non-uniform surface defects resulting in electrical noise, while a thicker layer of carriers finds a smoother path below the surface, thus reducing total electrical noise. This indicates that higher gate voltage translates to lower noise.

Referring to FIG. 2b , in the iFET 200, the electric field created by the gate voltage Vg on the gate control terminal 27 b causes carriers to rise from the substrate 26 b into the source channel 23 b region converting the semiconductor material to a conductor with a relatively large number of carriers per volume or at saturation, thus establishing a level of conductivity.

Injection current I_(inj) introduced into the iPort control terminal 21 b increases the diffused charge (number of carriers per volume) over and in the source channel 23 b, thus making the source channel 23 b even more conductive. The rate of conductivity change is exponential, similar to that found in “weak inversion.” This exponential rate of conductivity change is due to the low voltage gradient along the source channel 23 b (source terminal 24 b to iPort control terminal 21 b voltage gradient).

The iFET exponential relationship between source channel 23 b charge and gate voltage 27 b provides access to log functionality, where the addition of two log functions is equivalent to multiplication. A reverse anti-log, or reverse-exponential, operation recovers the analog output through the opposing complementary iFET channel. Such exponential relationship may be used for various low noise amplifier applications. The exponential relationship is also responsible for the wider dynamic range of these iFET circuits.

Again, referring to the source region in FIG. 2a , removing charge from the gate control terminal 27 a or/and iPort control terminal 21 a (number of carriers per volume) results in reduced conductivity of the semiconductor material in the source channel 23 a. In this respect, the iPort control terminal 21 a-to-source terminal 24 a connection operates in a manner similar to the base-region of a bipolar transistor (which is exponential): the more control current to the iPort control terminal 21 a, the more the device conductivity (g_(m)).

The drain channel 25 a of the iFET 200 of FIG. 2a operates more like a conventional FET, in that the thickness of the drain channel 25 a is greater near the iPort control terminal 21 a (same thickness as the source channel 23 a) and tapers as it reaches its diffusion region around the drain terminal 29 a (the decreasing voltage differential between drain channel 25 a and gate control terminal 27 a diminishes the field) establishing the output resistance of the transistor as set by the gate voltage V_(g). A lower drain voltage V_(g) (close to the voltage found on the gate), decreases the drain channel output resistance (thicker channel at the drain diffusion). Along with a thicker conduction layer, this lower drain channel resistance results in lower noise and a high output drive capability to establish the desired drain voltage at the drain 29 a with a low impedance drive offered by the thick conduction layer.

Diffusion regions around the source region 24 a of the iFET 200, operating at a low voltage, has lower voltage gain but it also has low noise. Diffusion region around the drain terminal 29 a, operating at a higher voltage, provides the desired voltage gain with a minimal noise contribution, due to the drain voltage being the same as the gate voltage V_(g). This voltage equality is contributed by a unique biasing construct, to be explained hereinafter.

FIG. 2b further shows iFET channel charge distributions, according to the present invention, with their operating points or iFET's characteristics without iPort injection current graphed in FIG. 2c , where the source channel current level 24 c and voltage level 25 c at the drain channel 25 b with no input current is applied to iPort control terminal 21 b. Slope 26 c represents drain channel 25 b am dots transresistance r_(m), while slope 23 c is for source channel 23 b which is super saturated, and iPort input resistance R_(in). FIG. 2d illustrates iFET's V-I characteristics with iPort injection current, where slop 26 d represents drain channel 25 b and its transresistance r_(m), while slope 23 d is for source channel 23 b which is super saturated, and iPort input resistance R_(in). It is to be noted that how a small amount 21 d of iPort current greatly disturbs the drain channel output voltage V_(out) 25 d. As it can be seen, V_(out) can swig to almost at full power supply (V_(dd)). This is the converse or dual of a normal voltage controlled current source use of the MOS device where large changes in the drain-to-source voltage yield minimal changes in the drain current during saturation as shown in FIG. 2d . This gives an analog IC designer insight as to the usefulness of the iFET as an amplifier which does not require a typical large, bulky analog planar transistor for the needed transconductance to obtain gain. Instead, the NiFET in a current-controlled voltage source configuration uses transresistance to boost the gain of the MOS-based device to new heights.

Non-Inverting Nature

Regarding the iPort control terminal, in the case of both the N-channel and P-channel devices, a positive current into the iPort control terminal displaces an equivalent current coming in through the drain channel, causing the drain (output) connection to move in a positive voltage direction—thus the non-Inverting nature of the iPort input.

The iPorts also operate as a current inverter as opposed to a conventional current mirror.

Interestingly, unlike other semiconductor devices, a negative current can be extracted from the iPort, causing a drain (output) shift in the negative direction. Zero input current is also valid.

Proper Bias

An iFET 200 (as shown in FIG. 2b ) has both gates connected together and requires a proper bias voltage on the gate to establish the desired operating point.

Symmetry

A P-channel device can be constructed and behaves in a similar fashion to its N-channel counterpart.

It should be emphasized that while the gate input is inverted with respect to the drain, the iPort is NOT inverted.

The CiFET Amplifier is the Basic Analog-in-DIGITAL Building Block:

While a single iFET has interesting characteristics on its own, a complementary pair of iFETs (or CiFET) prove to be much more beneficial. Using the opposite semiconductor type iFET as a load device conveniently provides the opposing iFET its bias and in addition has the advantage of balancing out (linearizing) the inherent non-linearities of MOSFET operation. For instance, the high-gain exponential characteristics of the source channel's super-saturated operation are linearized over an extremely wide dynamic range.

The resulting complementary device (the seminal CiFET cell) is arguably the highest possible power gain-bandwidth MOSFET amplifier stage possible. For instance, looking into either iPort, the super-saturated source channel input impedance is a relatively low number constant resistance. This converts any input current into a small input voltage, which calculates out to be a very high voltage gain transfer function implemented by the high number r_(m) trans-resistance. In addition, the sub-surface operation of the super-saturated source channel may operate with the lowest noise possible for any MOS device. The drain channel also maximally operates below its surface defects for low noise. In the end it is all about signal-to-noise ratio.

FIG. 3a presents the seminal CiFET symbol and FIGS. 3b and 3c show a diagrammatically similar physical layout abstraction; FIG. 3d shows three (3) dimensional perspective view and FIG. 3e illustrates cross-sectional view at Section AA in FIG. 3d ; and FIGS. 3f and 3g illustrate iPort control terminal behavioral model of a CiFET device of the present invention, self-bias schematic, and symbol therefor of a complementary pair of iFET of the present invention, which is a radical improvement from the state of the art in high gain, high precision, small scale, analog primitive building blocks. The complementary pairs of iFETs are built entirely from logic components, without analog extensions, while enabling scaling and portability. Both the footprint and the power consumption per gain/bandwidth are drastically reduced from the present state of the art, while retaining superior noise performance.

Referring to FIG. 3a , the complementary pair of iFETs (or CiFET) 300 comprises P-type iFET (or PiFET) 301 and N-type iFET (or NiFET) 302, comprising input terminal 30 a connected to both the gate control terminal 37 p of PiFET 301 and the gate control terminal 37 n of NiFET 302, function as the common gate terminal 30 a. CiFET 300 receives power, Power − and Power +, where Power − is connected to the source terminal of NiFET 302 and Power + is connected to the source terminal of PiFET 301. Each of PiFET 301 and NiFET 302 comprises iPort control terminals (31 a and 32 a) for receiving injection current. The drain terminal of PiFET 301 and NiFET 302 are combined to provide output 39 a.

FIG. 3b stretches out the CiFET 300 PiFET and NiFET devices 301 and 302 of FIG. 3a to visually correlate to the physical layout abstract of FIG. 3 c.

Referring to FIG. 3c , the CiFET 300 comprising PiFET 301 and NiFET 302, laid out on the substrate (or body B+ and B− respectively) like a mirror image along well border WB′ shown therein; PiFET 301 comprises source terminal S+, drain terminal D+, and iPort control terminal Pi, defining source+channel 34 c between the source terminal S+ and the iPort control terminal Pi diffusion region 32 c, and drain channel 36 c between the drain terminal D+ and the iPort control terminal Pi diffusion region 32 c. NiFET 302 comprises source terminal S−, drain terminal D−, and iPort control terminal Ni, defining source−channel 33 c between the source terminal S− and the iPort control terminal Ni diffusion region 31 c, and drain channel 35 c between the drain terminal D− and the iPort control terminal Ni diffusion region 31 c. CiFET 300 further comprises a common gate terminal 30 c over source+channel 34 c, drain+channel 36 c, source−channel 33 c and drain−channel 35 c. Accordingly, the common gate terminal 30 c is capacitively coupled to the channels 34 c, 36 c, 35 c, and 33 c.

FIG. 3d is a 3-Dimensional representation of the CiFET physical layout of FIG. 3c and FIG. 3e is a cross-section AA of FIG. 3d . The corresponding pinpoint numbers relate the same feature between each of FIGS. 3a, 3b, 3c, 3d, 3e, 3f, and 3g where the same feature is represented by the reference number with the figure letter annexed. FIG. 3h shows a symbol diagram for a CiFET device of the present invention. FIGS. 3d and 3e further points out the active channel charge conduction regions 34 d, 34 e, 36 d, 36 e, 33 d, 33 e, 35 d, and 35 e that exist for the biased CiFET which has its gate voltage at about half the difference between that on the S+ and S− terminals.

In many analog circuits, biasing is a problem. Using iFETs in complementary pairs (31 g & 32 g) as shown in FIG. 3g allows them to “self-bias” (38 g), thus eliminating drift problems and additionally, the amplifier finds the maximum gain point on its operating curve.

In the “Behavioral Model” as shown in FIG. 3f , the current at the iPort control terminals, NiPort 33 f and PiPort 34 f is converted to a voltage by a trans-resistance (r_(m)), whose value determines the gain. Self-bias path 38 f to V_(input) 30 f is provided for eliminating drift problems. This “Trans-resistance” (r_(m)) is established by the ratio of the “drain channel” to “source channel” strength, and remains constant throughout the entire operational range. Here the iFET operation is derived from different current densities in the source and drain channels, which is similar to a dual of the band-gap method of generating a reference voltage made by running the same current value through a single transistor and a parallel combination of multiple instances of an identical transistor. Simulation has shown this resistance (r_(m)) to typically be in the range of 1KΩ to 4MΩ with a typical value of 100KΩ, as set by the relative channel sizing. r_(m) is the dual of g_(m).

The output (V_(out) 39 f) is a low-impedance source follower common-gate FET configuration that can deliver its voltage with the necessary current to drive the following circuit.

The iPort input is a constant low resistance termination (related to r_(m) but much lower) with a constant offset voltage, CTAT Ref, PTAT Ref, of about 1 mV to 100 mV from their respective power supply rail. This offset voltage is a “bandgap” reference, established by the ratio of the “drain channel” to “source channel” strength.

A standard CiFET compound device cell can be physically constructed and instantiated like a logic cell for designing analog. Normally this is the only active circuit component needed. Like a transistor, but the CiFET cell does everything needed for an active component.

How then is the proper bias voltage produced? The simplest way of generating the bias voltage is to use iFETs in complementary pairs, NiFET 31 g and PiFET 32 g, creating an inverting device as shown in FIG. 3g , and then using the output 39 g to provide negative feedback 38 g to the input 30 g. The CiFET compound device will “self-bias” at a point between the power supplies, where the gain is maximized and the speed or slew rate is poised for its most rapid changes. At this self-bias voltage point, the current through both of the complementary iFET devices 31 g and 32 g is exactly equal, there is no other DC current path for the PiFET (32 g) drain except into the NiFET (31 g) drain, and thus a specific gate voltage is established for this equality of currents (or conductivity). Also since both iFETs 31 g and 32 g have the same current, the pull-up ability is exactly equal to the pull-down ability, which defines the maximum slew rate bias point. The current at the iPort control terminals, NiPort 33 g and PiPort 34 g is, then, converted to a voltage by a trans-resistance (r_(m)) (not shown), whose value determines the gain.

Since the complementary pair of iFETs 31 g and 32 g is self-biased, any parametric factors are auto-compensated, for changes in operating environment. Because of inherent matching between adjacent parts on an IC, the bias generator can be used to bias other iFETs nearby. The real-time self-biasing circuit corrects for parametric changes (in various forms).

Each of the transistors in an inverter of the present invention acts as a “dynamic” load for its complement, allowing the gate voltage to be significantly higher than the traditional bias point of an analog circuit gate. With the complementary iFET compound device's higher than normal gate voltage, the source conduction channel is deep, yielding lower noise.

The dominant noise source in a traditional analog circuit is related to “pinch-off.” Biasing the drain (or output) at the same voltage as the gate (zero differential) causes the drain conduction channel to avoid the channel pinch-off (shallow channel) phenomena usually encountered in analog circuits. Another way of stating this is: a transistor gets noisier as the drain approaches its design maximum voltage, the self-biased inverter operates its transistors at around half the design maximum voltage and the gate is at the same voltage as the drain (zero differential), therefore the self-biased inverter is MUCH quieter.

The operation of the CiFET amplifier differs from the operation of a conventional analog amplifier, with its current mirror loads, in that:

The “Source” channel has an extremely small (˜100 mv) voltage from source terminal to iPort control terminal while the “Gate terminal” is at ˜½ V_(supply). This puts the iFET Source channel into “Super-Saturation,” a condition similar to weak inversion but with high Gate overdrive. Gate overdrives resulting in an unusually thick conduction layer and along with a low Source to iPort voltage resulting in that conduction layer remaining thick all the way along the channel. Notice the differences in the thickness between the conduction channel 10 s in FIG. 1e from that of 23 b in FIG. 2 b.

The “Drain” channel 25 b operates with its' drain terminal 29 b at ˜½ Vmax, greatly reducing the pinch-off (and DIBBL) effect. This reduced pinch-off condition is further enhanced by the fact that the “Gate terminal” is operated at ˜½ V_(supply) (same as ½ Vmax), meaning no potential difference between the Drain 29 b and the Gate 27 b.

Another important aspect of the CiFET compound device is its current input that frees it from the speed robing effects of parasitic capacitance.

This subtle but significant difference is one of the enabling features that makes weak inversion work and gives the complementary iFET amplifier its superior low noise, wider dynamic range, and speed advantages.

MOSFETs do not make particularly good amplifiers compared to equivalent bipolar circuits. They have limited gain, they are noisy, and their high impedance makes them slow.

Bipolar Diff-Amps developed to the point where the input offset is pretty good, but the move to CMOS never really delivered as good a result.

It has long been known that superior performance can be had from CMOS operated in weak inversion but complications arising from high impedance, due to impractically low currents, preclude taking advantage of the superior gain (equivalent to that of bipolar transistors), dynamic range (exceeding that of bipolar transistors), and logarithmic performance (allowing numerous decades of amplification) found in weak inversion. Because of weak inversion the CiFET brings the noise benefits of majority carriers in a deep channel found in junction-FETs to the MOSFET.

While a MOSFET in weak inversion, working into a current source load, delivers a logarithmic transfer function, the same MOSFET working into an anti-log load cancels the nonlinearity, yielding a perfectly linear transfer function. The CiFET amplifier is such a circuit, i.e.: log input, antilog load, perfectly linear, wide dynamic range, low noise. The low noise is a consequence of the biasing, where the source channel gate potential is unusually high and the potential across the source channel itself is maintained at near zero volts. The drain channel is a level shifter, maintaining a very low voltage on the source channel while delivering high amplitude signal swings at the output.

The CiFET amplifier, implemented in a closed-loop, sample-data block delivers near perfect performance in terms of input offset because of its “flying capacitor” input. The CiFET amplifier, implemented in an open-loop, delivers unexpected levels of sensitivity (gain >1 million), even in the presence of high levels of background, this because of the extreme dynamic range.

FIGS. 3i, 3j (1) and 3 k shows a comparison between NOR2 and CiFET physical layouts. In particular, FIG. 3i shows a physical layout of NOR2 device with a corresponding symbol.

In the layout abstractions of FIGS. 3i, 3j (1), and 3 k, a metal layer (not shown) is added to connect their source/drain diffusion contacts (small squares) together. Namely, in FIG. 3j (1), drain terminals pout and nout are interconnected, one iPort Ni is connected to the other iPort Ni on NiFET 30 n, and one iPort Pi is connected to other iPorts Pi on PiFET 30 p. Parallel channels are used as needed to increase total channel width.

FIG. 3j (1) shows a physical layout of seminal CiFET, FIG. 3j (2) shows its corresponding schematic diagram, and FIG. 3j (3) illustrates its corresponding symbol, and FIG. 3k shows a physical layout of FinFET of complimentary pair of iFET (equivalent to the CiFET symbol shown in FIG. 3j ) of the present invention.

Referring to FIG. 3j (1), the layout 30 j includes layout for PiFET 30 p and NiFET 30 n, PiFET 30 p includes gate Gate, iPorts Pi, drain terminals pout and source terminal pst. Source channel ps is formed between the iPort Pi and source terminals pst, and the drain channel pd is formed between the drain terminals pout and iPort terminals Pi; while source channels ps1 and ps2 are formed between the source terminals pst and iPort terminals Pi. In a similar manner, NiFET 30 n includes iPorts Ni, drain terminals nout and source terminal nst. Source channel ns1 and ns2 is formed between the iPort ni and source terminals nst, and the drain channel nd is formed between the drain terminals nout and iPort terminals Ni.

Referring to FIG. 3k , the layout 30 k includes layout for PiFET 30′p and NiFET 30′n, PiFET 30′p includes gate Gate, iPorts P′i, drain terminals p′out and source terminal p′st. Source channels p′s1 a, p′s1 b, p′s1 c, and p′s2 a, p′s2 b, and p′s2 c, are formed between the iPort P′i and source terminals p′st, and the drain channels p′d1 a, p′d1 b and p′d1 c; and p′d2 a, p′d2 b and p′d2 c are formed between the drain terminals p′out and iPort terminals P′i. In a similar manner, NiFET 30′n includes iPorts N′i, drain terminals n′out and source terminal n′st. Source channels n′s1 and n′s2 are formed between the iPort N′i and source terminals n′st, and the drain channels n′d1 and n′d2 are formed between the drain terminals n′out and iPort terminals N′i.

Taking Advantage of the Doping Profile and Ratioing:

Traditionally engineers have avoided using digital logic in an analog configuration because it was believed to be unacceptably nonlinear and was difficult to bias. Digital logic also sacrifices drive symmetry for compactness. Restoring the symmetry through proper device ratioing (˜3:1 p:n width) improves linearity, increases noise immunity, and maximizes dynamic range. Self-biasing solves the bias problem.

FIG. 1q depicts the basic symbol and 3-dimensional view of the MOS transistor structure in saturation. The generic planar MOSFET here is shown with a typical longer/wider channel used in customary analog applications. The FET symbol and structure shown applies to either n- or p-type planar transistors which can further be related and applied to the wrapped-gate finFET structure as desired. Note that the FET has four ports including the gate (g) 17 q, drain (d) 19 q, source (s) 14 q, and body (b) 16 q. Typically, voltage is applied as input to the high-resistance gate port 17 q, while a voltage or current may be applied to the physically similar (and interchangeable) drain 19 q and source ports 14 q. The bulk/body port 16 q is generally attached to the lowest (or low) voltage potential for n-type FETs and highest (or high) voltage potential for p-type FETs to control/prevent forward biasing of the bulk-source junction and to give the lowest V_(gs) relative to the supply voltage for normal operation (although there are exceptions and special uses for the bulk, they will not be covered here). Additionally, the planar 3-dimensional MOSFET structure in FIG. 1q is shown with a wider width, W, and longer length, L, commonly used for analog circuits, along with a channel in the pinch-off saturation region.

In order to maintain a high intrinsic gain, the MOSFET requires a high output impedance. This is obtained through long channel lengths necessary for high r_(o)=R_(out). Since g_(m) is proportional to the W/L ratio of the MOSFET, in order to keep g_(m) high when the channel is long, the channel must also be proportionally wider. Gain here is ˜g_(m)R_(L)/R_(out). As the IC process shrinks, g_(m) increases, but R_(out) decreases faster, ruling out short channel lengths for analog. This is why as IC processes shrink analog transistors do not scale accordingly in the newest double-digit CMOS technologies. Also, it is to be noted that the analog channel current travels close to the surface under the gate where the surface defect carrier traps create the characteristic MOSFET 1/f noise.

FIG. 1r shows a physical layout plan of an array of Fin field effect transistors (FinFET) of prior art. Sources 14 r and drains 19 r are stacked and forms fins, and an array of gates 17 r are disposed therebetween to form FinFETs 12 r. Zoomed in view of the circle Z in FIG. 1r , which shows one of prior art three (3) dimensional perspective view of FinFET 12 r is shown in FIG. 1 s.

FIG. 1t shows a plot representing intrinsic gain scaling of nMOS transistor of prior art. As it can be seen, the steadily decreasing intrinsic gain of nMOS transistors alerts analog designers of impending difficulty that they face when attempting to scale the design of an amplifier that may have run efficiently at 65 nm or 90 nm to the 14 nm CMOS process, where it will most likely fail. Therefore, other methodologies which depart from conventional procedures must be explored in order to find a viable tactic to harness inherent transistor gain in the newer ultra-deep sub-μm CMOS technologies.

FinFETs have short nanoscale channel lengths that increase g_(m) while lowering the drain output resistance of the bare field effect transistor. Higher g_(m) provides better control over channel conductance, but the close proximity of the drain to the source makes them talk to each other making the output resistance low. This yields a low intrinsic gain of the MOSFET at nanoscale dimensions. Conversely the CiFET is a low output resistance device and improves with deep scaling.

According to the preferred embodiment of the present invention, noise figures can be particularly optimized on front end amplifiers through proper ratioing. The iFET's electrical characteristics can be enhanced by modifying the combined and relative strength of the source and drain channels, without modifying the available IC process (without analog extensions). There are several approaches to realizing this optimization (adjusting length, width, and threshold among others).

Nearly any source and drain channel size will make a functional iFET, but varying the individual iFET channel size, both relative and cumulative, increases the iFET performance depending on the objective.

Fundamentally:

-   -   Lower iPort impedance is achieved with a lower current density         (wider) source channel as compared to the drain channel.     -   Higher voltage gain is obtained through a higher resistance         (longer) drain channel as compared to the source channel, which         makes a higher output impedance looking into the drain terminal         (iFET Voltage gain=Drain channel resistance/Source channel         resistance).     -   The power verses speed tradeoff is controlled by the cumulative         sum of all of the channel strengths used to set the idle current         through the complementary iFET amplifier. This establishes the         output slew rate (or output drive capability).

To be clear, the strength of the iFET channels are a function of the individual channel width and lengths, as well as their thresholds. Each of the iFET channels can have individually selected sizes and/or threshold relationships to the other channel.

FIG. 2e shows various conventions/symbols for iFET devices of the present invention. Symbols 22 g and 24 g for PiFET, and symbols for NiFET 21 g and 23 g are shown. For example, NiFET 21 g or 23 g represents an n-type iFET (or NiFET) with shorter source channel as previously described, and thus, as it can be seen, NiPort is shown near the Source. An example sizing of the NiFET device 21 g may be, for drain channel with W_(min)/2×L_(min) while the source channel is 2×W_(min)/L_(min) for a combined iFET drain:source ratio of 4. This NiFET would allow for lower input iPort termination resistance targeting current gain objectives, which is useful for high gain current input trans-impedance amplifier applications. Similarly, PiFET 22 g or 24 g is shown to have PiPort near the Source as well which signifies wider source channel. Example sizing of the PiFET device 22 g may be, for drain channel with 3×W_(min)/2×L_(min), while the source channel may be 6×W_(min)/L_(min) for combined iFET drain:source ratio also of 4, but with 3× PiFET to NiFET ratio adjusting for similar PiFET to NiFET overall strength, roughly balancing P to N total channel conductance.

While iFET amplifiers can be constructed with minimum sized devices which do provide ample current at the output for very fast response and high accuracy, care must be exercised so that the complementary iFET amplifier does not pass too much current, subjecting it to mechanical failure. The physical layout requires enough contacts and metal for the required DC and transient currents.

Noise Advantages:

In the end, it comes down to signal-to-noise ratio. Low power supply voltage requirements in ultra-deep-sub-μm IC processes limit the maximum signal swing to a much smaller number than most analog designers are used to. So with a smaller signal, the noise must be equally small in order to maintain the desired signal to noise ratio. It is imperative that noise issues be reduced. This iFET amplifier technology not only reduces noise by an amount as would be necessary, but performs far beyond expectations, delivering ultra-quiet front ends.

1/f noise in the source channel is reduced because the self-bias scheme provides a high field strength on the source channel's gate, forcing carriers in the channel to operate below the surface where there is a smoother path (fewer obstructions) than along the surface where crystal lattice defects interfere.

1/f noise in the drain channel is also low. Unlike conventional analog designs, the gate is self-biased at the half-way point between the power supply rails as is the drain, while the iPort is within ˜100 millivolts of the power rail. With the high electric field along the drain channel, and the gate voltage equal to the drain terminal voltage, the carriers are constrained to flow mostly below the channel surface. This keeps the drain channel out of pinched off conditions, where unwanted 1/f noise would be generated.

Resistor noise is reduced because the self-bias configuration puts the complementary pair at its lowest channel resistance operating point. Resistance is caused by collisions, between carriers and the surrounding atoms in the conductor. The lower the resistance is, the fewer the collisions are.

Wide band noise (white-noise) would always be an issue in high gain for high frequency circuits. While conventional designs adjust the gate voltage to establish suitable operating point(s), the designs of the present invention establish the gate voltage at the optimum point (the “sweet-spot”) and then adjust the load to establish the desired operating point. This approach establishes a higher quiescent current where (for reasons explained above) higher current density circuits have lower wide band noise.

High common mode power supply rejection is inherent in the complementary iFET circuit of the present invention. Signals are with respect to the mid-point instead of being with respect to one of the power supply rails, (similar to an op-amp with its “virtual” ground). Power supply noise is from one rail to the other, equal and opposite in phase with respect to each other; thus canceling around the mid-point.

Ground-Loop noise is diminished because the circuit ground is “virtual” (just like in many op-amp circuits), rather than ground being one or the other power supply connections. In the closed-loop case, “Flying capacitors” (or “input voltage sampling capacitors”) are employed. With “flying capacitors” there is no direct electrical connection between stages, so there is no common ground; virtual or otherwise. The use of “differential decoupling” (flying capacitors) offers transformer like isolation between stages, with the compactness of integrated circuit elements.

Coupled noise from “parasitic induced crosstalk” increases by the square of the signal amplitude. Unintended capacitive coupling with a 1 volt signal causes a lot more trouble than with a 100 mV signal, by a factor of 100:1 (square law effect). The small voltage signals employed in the analog sections, reduce this capacitive coupled interference substantially. Nearby Digital signals will, by definition, be high amplitude (rail-to-rail). Good layout practices are still the best defense against this digital source of noise.

Additional Advantages:

There are a number of additional advantages. For example, bi-directional control on the iPort means that current can flow in-to as well as out of this connection; both directions having a significant control effect on overall channel current. The iPort has about five (5) orders of magnitude more dynamic control range than the gate.

The iFET of the present invention yields an analog structure that is significantly faster than logic using the same MOS devices. This speed improvement is due to the fact that the complementary structure expresses its maximum gain (and highest quiescent current) at its natural self-bias point, midway between the power supplies.

Since the iPort voltage does not significantly change, it is immune to the R/C time constant effects of the surrounding parasitics, thus the iPort (current) input responds faster than the gate (voltage) input.

Since in most applications of the CiFET compound device of the present invention, the output voltage (drain connection point) does not vary greatly, and thus making the output immune to the R/C time constant effects of the surrounding parasitics. A logic signal is slower than analog here because logic signals have to swing from rail to rail.

Drain-induced barrier lowering or (DIBL) threshold reduction is avoided in the CiFET compound device operating in the analog mode. When gain and threshold voltage is important, the drains are operating around half of the power supply voltage, thus eliminating the higher drain voltages where DIBL effects are prevalent.

Bandgap reference circuits are very important to analog circuits. Analog ICs require a stable reference for critical values such as voltage, which can change with a variation of temperature. Circuit performance is wholly dependent on correct biasing, and any fluctuations can render a design incorrect or even inoperable. Therefore, reference circuits, can be used to check for changes so that the necessary corrections made to allow the circuit to perform well. The compact self-biased CiFET has been found to be a useful as proportional-to-absolute-temperature (PTAT) circuit as shown in FIG. 4 a.

The circuit diagram shown in FIG. 3m is a prior art proportional to absolute temperature (PTAT) circuit proposed by Christoffersen, C. et al., “An Ultra-Low Power CMOS PTAT Current Source,” IEEE-EMATA 2010, pg. 35-40. As it is shown, such prior art circuit requires a large number of component counts, including at least 41 large transistors. It further requires multiple bias-currents to have this work, and thus it is anticipated that this prior circuit would have much higher power dissipation. Due to the large component count, it is further anticipated that this prior art circuit would further require larger area. In addition, it is further anticipated that this prior art circuit would be very sensitive to temperature and humidity. It would further require multiple matching devices for accuracy as well. Accordingly, there is a long felt need for improving at least one aspect of the prior art circuitry.

FIG. 4a shows a schematic diagram of a CiFET voltage reference circuit 100 in accordance with a preferred embodiment of the present invention. FIG. 4b shows a schematic diagram of CiFET current source circuit 150 in accordance with a preferred embodiment of the present invention.

FIG. 4a shows a voltage reference circuit constructed with a CiFET amplifier, including an NiFET Q104 and a PiFET Q105. Power supply voltage Vss (negative supply voltage) is connected to the source terminal 104 s of the NiFET Q104, and Vdd (positive supply voltage) are connected to source terminal 104 s of PiFET Q105 a. Drain terminals 104 d and 105 d of the NiFET Q104 a and PiFET Q105 a, respectively, are connected together and provide analog zero bias reference 100bias and to the common gate 100 cg, which connects to the gate terminals 104 g and 105 g of NiFET Q104 a and PiFET Q105 a, respectively. Stable repeatable voltages, with settable range of ˜1 mv to ˜100 mV, is presented on the iPorts control terminals 1041 (or lower rail bandgap reference 100LR) and 105 i (or upper rail bandgap reference 100UR). This is a type of bandgap reference voltage created by forcing the exact same current to pass through two different MOS channel width transistor channels connected in series, while these MOS transistor channels share the same gate voltage. The N-channel iPort (or iPort control terminal) 104 i of NiFET Q104 presents a bandgap reference above Vss (or negative supply voltage) while the P-channel iPort (or iPort control terminal) 105 i of PiFET Q105 presents its bandgap reference voltage below Vdd (or positive supply voltage).

In FIG. 4c , it can be seen that the voltage output is linear over an extremely wide range of temperatures. Additionally, the present graph illustrates that the lower rail bandgap reference 100LR (proportional to absolute temperature or PTAT) and upper rail bandgap reference 100UR (complementary-to-absolute-temperature or CTAT) voltages are of the same magnitude—with precisely the opposite slope—and can be setup by the iFET ratios. Therefore, the circuit 100 in FIG. 4a makes an ideal voltage reference—as a designer can set the voltage simply through the W/L ratios of the iFETs. The CiFET PTAT/CTAT is compact, low power, shows good power supply rejection ratio (or PSSR), and is scalable into ultra-deep sub-μm CMOS processes.

FIG. 4c illustrates the NiPort PTAT and PiPort CTAT voltages tracking one another over extreme temperature limits. The NiPort PTAT voltage is measured up from the CiFET negative supply terminal voltage and the PiPort CTAT voltage is measured down from the CiFET positive supply terminal voltage. Thus these reference voltages are the iPort voltage away from their respective iFET source terminals and are a linear function of temperature. They are set by the various CiFET ratios and can be trimmed with small iPort current injection. Switch capacitor sampled data techniques can be used to generate various reference functions. Combinations of these voltages can also be stacked as shown in FIG. 4 d.

The voltage reference circuit 160 in FIG. 4d is another example of the usefulness of the CiFET seminal cell. The circuit 160 includes four (4) CiFETs, namely first CiFET including NiFET Q104A and PiFET Q105A; second CiFET NiFET Q104B and PiFET Q105B; third CiFET NiFET Q104C and PiFET Q105C; and fourth CiFET NiFET Q104D and PiFET Q105D. For each of CiFETs, as previously described for FIG. 4a , gate terminals 104Ag and 105Ag; 104Bg and 105Bg; 104Cg and 105Cg; and 104Dg and 105Dg are connected together to form common gate terminals, 100Acg; 100Bcg; 100Ccg; and 100Dcg; respectively. Similarly, for each CiFET, drain terminals 104Ad and 105Ad; 104Bd and 105Bd; 104Cd and 105Cd; 104Dd and 105Dd; are connected together to form output 100Ao; 100Bo; 100Co; and 100Do, respectively, and each output 100Ao; 100Bo; 100Co; or 100Do are connected back to the corresponding common gate 100Acg; 100Bcg; 100Ccg; and 100Dcg, respectively, as bias therefor. In practice, the source terminal 105As of PiFET Q105A is connected to the positive voltage power supply V_(dd); while the source terminal 104As of NiFET Q104A is connected to the negative voltage power supply V_(ss). As previously stated, iPort 105Ai of PiFET Q105A provides CTAT reference voltage; iPort 104Ai of NiFET Q104A provides PTAT reference voltage.

The following CiFET, the source terminal 104Bs of NiFET Q104B receives the PTAT reference voltage generated from the iPort 104Ai of the previous NiFET 104A; the source terminal 105Bs of PiFET Q105B receives the CTAT reference voltage generated from the iPort 105Ai of the previous PiFET 105A; and the common gate 100Bcg receives the output 100Ao of the previous CiFET NiFET Q104A and PiFET Q105A. Similarly, the following CiFET NiFET Q104C and PiFET Q105C, the source terminal 104Cs of NiFET Q104C receives the PTAT reference voltage generated from the iPort 104Bi of the previous NiFET 104B; the source terminal 105Cs of PiFET Q105C receives the CTAT reference voltage generated from the iPort 105Bi of the previous PiFET 105B; and the common gate 100Ccg receives the output 100Bo of the previous CiFET NiFET Q104B and PiFET Q105B. This may further be repeated. For example, the following CiFET NiFET Q104D and PiFET Q105D, the source terminal 104Ds of NiFET Q104D receives the PTAT reference voltage generated from the iPort 104Ci of the previous NiFET 104C; the source terminal 105Ds of PiFET Q105D receives the CTAT reference voltage generated from the iPort 105Ci of the previous PiFET 105C; and the common gate 100Dcg receives the output 100Co of the previous CiFET NiFET Q104C and PiFET Q105C. Here the bias and iPort reference voltages are set by the ratioing of the W/L vales in the iFET. The circuit 160 is self-biased, compact, low power, and can operate at low supply voltages in a deep sub-μm and nanoscale CMOS processes including FinFETs.

FIG. 4b shows yet another example of a current source circuit 150, comprising a circuit similar to a voltage reference generator circuit shown in FIG. 4a , including NiFET Q104 a and PiFET Q105 a, and additional iFET devices Q106 and Q107 for generating current outputs 150 a and 150 b. Drain terminals 104 ad and 105 ad of NiFET Q104 a and PiFET Q105 a are connected together for providing bias Bias to the gate control terminals 104 ag and 105 ag, and 106 g and 107 g of NiFET Q104 a and PiFET Q105 a and NiFET Q106 and PiFET Q107 The upper rail bandgap reference 100UR is fed from iPort terminal 105 ai of PiFET Q105 a to iPort terminal 107 i of PiFET Q107 for generating current 150 b, and the lower rail bandgap reference 150LR is fed from iPort terminal 104 ai of NiFET Q104 a to iPort terminal 106 i of NiFET Q106 for generating current 150 a. These currents can be useful for biasing sensors such as photodiodes.

FIG. 4e shows a schematic diagram of reference voltages generator 170 related to analog virtual ground (CiFET self-bias) voltage in accordance with the present invention. The generator 170 includes two complementary pairs of CiFETs, first pair includes NiFET N150A and PiFET P150A, and second pair includes NiFET N150B and PiFET P150B. A source terminal P150Aa of PiFET P150A is coupled to positive power supply Vdd; a source terminal N150Ba of NiFET N150Ba is coupled to negative power supply Vss; drain terminals P150Ac and N150Ac of the first pair P150A and N150A are connected together; drain terminals P150Bc and N150Bc are also connected together; and source terminal N150Aa, source terminal P150Ba and gate terminals N150Ad, P150Ad, N150Bd and P150Bd are all connected together. In this configuration, a first output 170 a references +power or positive power supply voltage Vdd; a second output 170 b, which is iPort P150Ab of PiFET P150A generates complementary-to-absolute-temperature (or CTAT) reference voltage related to positive power supply Vdd; a third output 170 c, which is iPort N150Ab of NiFET N150A, generates a proportional-to-absolute-temperature (or PTAT) reference voltage related to analog ground voltage 170 d;

a fourth output 170 d generates analog ground; a fifth output 170 e, which is iPort terminal P150Bb of PiFET P150B, generates complementary-to-absolute-temperature (or CTAT) analog reference voltage related to analog ground 170 d; a sixth output 170 f, which iPort terminal N150Bb of NiFET N150B, generates a proportional-to-absolute-temperature (or PTAT) reference voltage related to power ground (Vss); and a seventh output 170 g references power ground, or negative power supply Vss.

Definitions of Terms

iFET: A 4 terminal (plus body) device similar to a Field Effect Transistor but with an additional control connection that causes the device to respond to current input stimulus.

source channel: A semiconductor region between iPort diffusion and the Source diffusion. Conduction in this region is enabled by an appropriate voltage on the Gate.

drain channel: A semiconductor region between Drain diffusion and the iPort diffusion. Conduction in this region is enabled by an appropriate voltage on the Gate.

CiFET: A single stage, complementary iFET compound device shown in FIG. 3 a.

super-saturation: an exponential conduction condition similar to weak inversion, but with high Gate overdrive and forced low voltage along the conduction channel. FIG. 2b #23 b.

feed-forward: A technique to present a signal on an output, early on, in anticipation of the ultimate value.

self-biased: Unlike fixed-bias circuits, self-biased circuits adjust to local conditions to establish an optimum operating point.

dual: (of a theorem, expression, etc.) related to another by the interchange of pairs of variables, such as current and voltage as in “Trans-Conductance” to “Trans-Resistance.”

trans-resistance: infrequently referred to as mutual resistance, is the dual of Trans-conductance. The term is a contraction of transfer resistance. It refers to the ratio between a change of the voltage at two output points and a related change of current through two input points, and is notated as r_(m):

$g_{m} = \frac{\Delta \; I_{out}}{\Delta \; V_{in}}$ $r_{m} = \frac{\Delta \; V_{out}}{\Delta \; I_{in}}$

The SI unit for Trans-resistance is simply the ohm, as in resistance.

For small signal alternating current, the definition is simpler:

$g_{m} = \frac{i_{out}}{\; v_{in}}$ $r_{m} = \frac{\; v_{out}}{\; i_{in}}$

trans-impedance: similar to trans-resistance, but further includes complex variables for high frequency applications.

trans-conductance is a property of certain electronic components. Conductance is the reciprocal of resistance; Trans-conductance is the ratio of the current variation at the output to the voltage variation at the input. It is written as g_(m). For direct current, Trans-conductance is defined as follows:

$g_{m} = \frac{\Delta \; I_{out}}{\Delta \; V_{in}}$ $r_{m} = \frac{\Delta \; V_{out}}{\Delta \; I_{in}}$

For small signal alternating current, the definition is simpler:

$g_{m} = \frac{\; i_{out}}{\; v_{in}}$ $r_{m} = \frac{\; v_{out}}{\; i_{in}}$

Trans-conductance is a contraction of transfer conductance. The old unit of conductance, the mho (ohm spelled backwards), was replaced by the SI unit, the Siemens, with the symbol S (1 siemens=1 ampere per volt).

translinear circuit: translinear circuit is a circuit that carries out its function using the translinear principle. These are current-mode circuits that can be made using transistors that obey an exponential_current-voltage characteristic—this includes BJTs_and CMOS transistors in weak inversion.

subthreshold conduction or subthreshold leakage or subthreshold drain current is the current_between the source and drain of a MOSFET when the transistor is in subthreshold region, or weak-inversion region, that is, for gate-to-source voltages below the threshold voltage. The terminology for various degrees of inversion is described in Tsividis. (Yannis Tsividis (1999). Operation and Modeling of the MOS Transistor (Second Edition ed.). New York: McGraw-Hill. p. 99. ISBN 0-07-065523-5.)

Subthreshold slope: In the subthreshold region the drain current behavior—though being controlled by the gate_terminal—is similar to the exponentially increasing current of a forward biased diode. Therefore a plot of logarithmic drain current versus gate voltage with drain, source, and bulk voltages fixed will exhibit approximately log linear behavior in this MOSFET operating regime. Its slope is the subthreshold slope.

Diffusion current: Diffusion current is a current_in a semiconductor_caused by the diffusion_of charge carriers (holes and/or electrons). Diffusion current can be in the same or opposite direction of a drift current, that is formed due to the electric field_in the semiconductor. At equilibrium in a p-n junction, the forward diffusion current in the depletion region is balanced with a reverse drift current, so that the net current is zero. The diffusion current and drift current together are described by the drift-diffusion equation.

Drain-induced barrier lowering: Drain-induced barrier lowering or DIBL is a short-channel effect in MOSFETs referring originally to a reduction of threshold voltage_of the transistor_at higher drain voltages.

As channel length decreases, the barrier φ_(B) to be surmounted by an electron from the source on its way to the drain reduces.

As channel length is reduced, the effects of DIBL in the subthreshold region (weak inversion) show up initially as a simple translation of the subthreshold current vs. gate bias curve with change in drain-voltage, which can be modeled as a simple change in threshold voltage with drain bias. However, at shorter lengths the slope of the current vs. gate bias curve is reduced, that is, it requires a larger change in gate bias to effect the same change in drain current. At extremely short lengths, the gate entirely fails to turn the device off. These effects cannot be modeled as a threshold adjustment.

DIBL also affects the current vs. drain bias curve in the active mode, causing the current to increase with drain bias, lowering the MOSFET output resistance. This increase is additional to the normal channel length modulation effect on output resistance, and cannot always be modeled as a threshold adjustment.

PSSR stands for power supply rejection ratio, defined as:

${PSSR} = {20\; {{\log_{10}\left( {\frac{\Delta \; V_{dd}}{\Delta \; V_{out}}A} \right)}\lbrack{dB}\rbrack}}$

where A is the gain of the circuit. Some manufacturers base PSSR on the offset voltage to the amplifier input and others base the PSSR on the voltage output as shown in the example equation. 

What is claimed is:
 1. A proportional to absolute temperature reference voltage circuit, comprising: a complementary pair of a n-type current field-effect transistor (NiFET) and a p-type current field-effect transistor (PiFET), each of said NiFETs and PiFETs comprises: a source terminal, a drain terminal, a gate terminal, and a diffusion terminal of a corresponding conductivity type of said each of said PiFET and NiFET, defining a source channel between said source terminal and said diffusion terminal, and a drain channel between said drain terminal and said diffusion terminal, said diffusion terminal causes changes in said diffused charge density throughout said source and drain channels, and said gate terminal is capacitively coupled to said source channel and said drain channel; wherein said gate terminal of said PiFET and said gate terminal of said NiFET are connected together to form a common gate terminal, said source terminal of said NiFET is connected to negative power supply and said source terminal of said PiFET is connected to positive power supply, and drain terminals of said NiFET and said PiFET are connected together to form an output; and wherein said common gate of said complimentary pair is connected together with said output of said complementary pair for generating a analog zero reference voltage, providing a positive rail complementary-to-absolute-temperature (or CTAT) reference voltage output at said diffusion terminal of said PiFET and a negative rail proportional-to-absolute-temperature (or PTAT) reference voltage output at said diffusion terminal of said NiFET.
 2. A positive and negative current references generator, comprising a. first and second complementary pairs of a n-type current field-effect transistor (NiFET) and a p-type current field-effect transistor (PiFET), each of said NiFETs and PiFETs comprises: a diffusion terminal of a corresponding conductivity type of said each of said PiFETs and NiFETs, a source terminal, a drain terminal and a gate terminal, said drain terminal defines a source channel between said source terminal and said diffusion terminal, and a drain channel between said drain terminal and said diffusion terminal, said diffusion terminal causes changes in said diffused charge density throughout said source and drain channels, and said gate terminal capacitively coupled to said source channel and said drain channel; wherein, for each complementary pair, said gate terminal of said PiFET and said gate terminal of said NiFET are connected together to form a common gate terminal, said source terminal of said NiFET is connected to negative power supply and said source terminal of said PiFET is connected to positive power supply, and said drain terminals of said NiFET and said PiFET are connected together to form an output; wherein said common gates of said first and second complementary pairs are connected together with said output of said first complementary pair, providing a positive rail complementary-to-absolute-temperature (or CTAT) reference voltage output at said diffusion terminal of said PiFET of said first complementary pair to said diffusion terminal of said PiFET of said second complementary pair for generating said negative reference current; and providing a negative rail proportional-to-absolute-temperature (or PTAT) reference voltage output at said diffusion terminal of said NiFET of said first complementary pair to said diffusion channel of said NiFET of said second complementary pair for generating said positive reference current.
 3. A stacked proportional to absolute temperature reference voltage circuit, comprising: a plurality of complementary pairs of a n-type current field-effect transistor (NiFET) and a p-type current field-effect transistor (PiFET), each of said NiFETs and PiFETs comprises: a source terminal, a drain terminal, a gate terminal, and a diffusion terminal of a corresponding conductivity type of said each of said PiFET and NiFET, defining a source channel between said source terminal and said diffusion terminal, and a drain channel between said drain terminal and said diffusion terminal, said diffusion terminal causes changes in said diffused charge density throughout said source and drain channels, and said gate terminal capacitively coupled to said source channel and said drain channel; wherein said gate terminal of said PiFET and said gate terminal of said NiFET are connected together to form a common gate terminal, and drain terminals of said NiFET and said PiFET are connected together to form an output; and wherein said common gate of said complimentary pair is connected together with said output of said complementary pair for generating a analog zero reference voltage, providing a positive rail complementary-to-absolute-temperature (or CTAT) reference voltage output at said diffusion terminal of said PiFET and a negative rail proportional-to-absolute-temperature (or PTAT) reference voltage output at said diffusion terminal of said NiFET wherein said source terminal of said NiFET of a first one of said plurality of said complementary pairs is connected to negative power supply and said source terminal of said PiFET of said first one of said plurality of said complementary pairs is connected to positive power supply, said source terminal of said NiFET of a subsequent one of said plurality of said complementary pairs receives PTAT reference voltage output of a previous one of said plurality of said complementary pairs; said source terminal of said PiFET of said subsequent one of said plurality of said complementary pairs receives CTAT reference voltage output of said previous one of said plurality of said complementary pairs; and said common gate of said subsequent one of said plurality of said complementary pairs receives said output of said previous one of said plurality of said complementary pairs.
 4. A proportional-to-absolute temperature reference voltages and complementary-to-absolute temperature reference voltages generator circuit, comprising: a. a first complementary pair of a n-type current field-effect transistor (NiFET) and a p-type current field-effect transistor (PiFET), b. a second complementary pair of NiFET and PiFET; each of said NiFETs and PiFETs comprises: i. a source terminal, a drain terminal, a gate terminal, and a diffusion terminal of a corresponding conductivity type of said each of said PiFET and NiFET, defining a source channel between said source terminal and said diffusion terminal, and a drain channel between said drain terminal and said diffusion terminal, said diffusion terminal causes changes in said diffused charge density throughout said source and drain channels, and said gate terminal is capacitively coupled to said source channel and said drain channel; wherein said drain terminals of said NiFET and said PiFET of said first complementary pair are coupled together; said drain terminals of said NiFET and said PiFET of said second complementary pair are coupled together; said source terminal of said PiFET of said first complementary pair receives a positive power supply; said source terminal of said NiFET of said second complementary pair receives a negative power supply; wherein said gate terminals of said PiFETs of said first and said second complementary pairs and said gate terminals of said NiFETs of said first and second complementary pairs are connected together to form a common gate and to receive said source terminal of said NiFET of said first complementary pair and said source terminal of said PiFET of said second complementary pair for generating a positive rail complementary-to-absolute-temperature (or CTAT) reference voltage output at said diffusion terminal of said PiFET of said first complementary pair, CTAT analog ground reference voltage output at said diffusion terminal of said NiFET of said first complementary pair, an analog ground reference voltage at said common gate, a negative rail proportional-to-absolute-temperature (or PTAT) reference voltage output at said diffusion terminal of said NiFET of said second complementary pair. 